Method for imparting elasticity to a non-woven material / elastomer laminate

ABSTRACT

Method for imparting elasticity to a laminate comprising at least one elastic film having a width and at least one ply of non-woven material secured to the film, particularly through interposition of a bonding material, particularly glue, which comprises the following steps in which: 
     the laminate is unrolled in the form of a web in order to pass it between two sets of toothing, of which the teeth engage in each other in a direction perpendicular to the plane of the laminate in order to thus stretch the laminate in the direction of its width, characterised in that: 
     a tension is imparted to the web in the longitudinal direction or machine direction during its unrolling between the toothing, particularly by providing a tensioner roll, particularly downstream of the sets of toothing.

CROSS-REFERENCE TO RELATED APPLICATION

This application is a division of U.S. patent application Ser. No.11/788,231 which was filed on Apr. 19, 2007, and issued as U.S. Pat. No.8,318,071 on Nov. 27, 2012.

TECHNICAL FIELD

The present invention relates to a method for imparting elasticity to alaminate comprising at least one elastic film, particularly with anelastomer base, particularly thermoplastic, and at least one ply ofnon-woven material secured to the elastic film. The present inventionalso relates to a device for imparting elasticity to a laminate of thistype, and also to a laminate of this type.

BACKGROUND ART

A laminate comprising at least one elastic film, particularly with anelastomer base, particularly thermoplastic, and at least one ply ofnon-woven material secured to the elastic film, is used in particular inapplications in the field of clothing, in particular throwaway, such astraining pants or devices for adult incontinence, or in the medicalfield in the form of elastic bandages. In the field of training pants,these laminates are conventionally used in the sections forming thewaistband around the waist of the baby. In particular these laminatesare used to realise the elastic tabs ensuring that the nappy is kept onthe baby and supporting, amongst other things, a hook and loop fastener.In general the securing of the nappy or sheet of non-woven material tothe elastic film is realised through the interposition of a bondingmaterial, particularly glue, either continuously between the non-wovenmaterial and the elastic or in discrete zones, in particular in pointsor in lines. The securing of the non-woven material and the elastic filmmeans that it is necessary to impart elasticity to the laminate bystretching it. This is an operation traditionally called “activation” inthe field of training pants. In fact, before the laminate has beenstretched it does not really have any elasticity or at least in the caseof using non-woven fabric having a slight elasticity, it only has aslight elasticity compared to non-woven fabric. After activation, thatis to say after the stretching of the laminate in its entirety, thelaminate will have, by reason of a sort of breaking or coming-apart orde-cohesion of the fibres of the non-woven fabric, an elasticity whichwill correspond to that of the elastic film, of which the elasticcapacities will thus have been released.

In order to realise this activation, it is known that the laminate canbe passed in the form of a web or composite between two toothed rolls,of which the teeth engage in each other. The teeth of the rolls extendessentially perpendicularly to the direction of unrolling of the web(machine direction). The mutual engagement of the teeth while thelaminate is between the two sets of toothing brings about the stretchingof the laminate. Upon leaving the two rolls, the laminate assumesessentially the form which it had prior to entering the rolls. However,the distortion which takes place means that, now, the laminate as awhole has elasticity, namely a transverse elasticity between its initialwidth and its final width (in the non-stretched state) and the maximumwidth which it has when it is between the two toothed rolls. Thelaminate has thus been activated.

It is already known from the prior art and in particular the U.S. Pat.No. 5,167,897 that an activation of this kind can be realised. The webis unrolled therein with a virtually zero longitudinal tension and theouter peripheral edges of the laminate adjacent to the region to beactivated are maintained, for example by depression or belt systems,during the action of the toothed rolls. The device used in its entiretyis quite complicated, requiring in particular complex systems formaintaining the outer peripheral edges adjacent to the region of thelaminate to be activated. Besides, the laminate obtained by thesemethods of the prior art presents risks of delamination or becomingunstuck at the outer edge of the laminate between the non-woven materialand the elastomer in such a way that it is necessary to provide eitherglues with a strong sticking power or a solder line, particularlyultrasonic, along these edges.

DISCLOSURE OF THE INVENTION

The present invention aims to overcome the drawbacks of the prior art byproposing a method for imparting elasticity to a laminate of the typementioned above which, on the one hand, is simpler to implement and inparticular does not require the maintaining of the adjacent outerperipheral edges of the section of the laminate to be activated andwhich, on the other hand, allows a laminate to be obtained, of which theconnection between the elastomer and the non-woven material has lesstendency to become unstuck at the outer edges in such a way that it maybe possible to omit the provision of solder lines along these edges.

According to the invention a method for imparting elasticity to alaminate comprising at least one elastic film having a width and atleast one ply of non-woven fabric secured to the film, particularlythrough the interposition of a bonding material, particularly glue,which comprises the steps in which:

-   -   the laminate is unrolled in the form of a web in order to pass        it between two sets of toothing, of which the teeth engage in        each other in a direction perpendicular to the plane of the        laminate in order to thus stretch the laminate in its width, is        characterised in that:    -   a tension is imparted to the web in longitudinal direction or in        the machine direction during its unrolling between the toothing,        particularly by providing a tensioner roll, particularly        downstream of the sets of toothing.

A very simple system is thus obtained according to the invention which,in particular, does not necessitate the provision of complicated meanswhich maintain the outer peripheral edges of the laminate to beactivated during its activation and which, however, allows a laminate tobe obtained, of which the connection between the elastomer and thenon-woven material is more resistant to becoming unstuck, particularlyat the outer edges, in such a way that it may be possible to omit anultrasonic solder line or to provide less costly glues than in the caseof the laminates of the prior art.

According to a preferred embodiment of the invention, a tension of atleast 1 Newton (N) is applied for 10 mm of width and 100 g/m² of saidwidth of the laminate to be activated; preferably, the tension is atleast 2 N/10 mm/100 g/m², more preferably at least 2.5, for examplebetween 1.2 and 8, in particular between 2 and 5, for example equal to2.6.

According to a preferred embodiment of the invention a tension isimparted of at least 0.64 Newton (N) for 10 mm of width and 100 g/m² ofply of non-woven material; preferably, the tension is at least 0.9 N/10mm/100 g/m² of non-woven material, more preferably at least 1.2, forexample between 0.65 and 3, in particular between 1 and 2, for exampleequal to 1.3.

According to a preferred embodiment of the invention the elastomer filmis extruded and deposited on the ply of non-woven material in a softenedstate, whereby the composite is then activated.

The composite thus only has one or two plies of non-woven material andintermediate layers of glue.

The present invention also relates to a device for imparting elasticityto a laminate comprising at least one elastic film having a width and atleast one ply of non-woven material secured to the film, particularlythrough the interposition of a bonding material, particularly glue,whereby the device comprises means for unrolling the laminate in orderto pass it between first toothing and between second toothing, of whichthe teeth engage mutually in each other in a direction essentiallyperpendicular to the unrolling plane of the web, characterised in thatmeans are provided for imparting a longitudinal tension to the unrolledlaminate.

According to a preferred embodiment of the invention, the means forimparting tension are constituted by at least one idler roll,particularly two rolls arranged upstream and downstream of the first andsecond teeth.

According to a preferred embodiment of the invention, the first andsecond sets of toothing are each constituted by toothed rolls.

The present invention also relates to a laminate comprising at least oneply of non-woven material, preferably two plies of non-woven material,and at least one elastic film having a width and secured to said atleast one ply, particularly being sandwiched between the two plies ofnon-woven material, particularly through the interposition of a bondingmaterial, particularly glue, whereby the laminate, in cross-section, insaid width, has an activated width (in which the elasticity is notessentially zero, that is to say it is greater than that of the laminatealone) which is less than or equal to said width and in which it hasbeen activated, whereby the activated width has a left region and aright region, whereby the elasticity of the laminate, measured inparticular through the elongation test at 10 Newton, increases from theleft edge of the activated width over at least a section of the leftregion and decreases over at least a section of the right region towardsthe right edge of the activated width.

Unlike the laminates of the prior art which have an elasticity in theactivated width which is essentially constant or uniform, the laminateaccording to the invention has a greater elasticity towards the centrethan in the edge sections of said width. This gradient (or variation) ofthe elasticity and in particular the fact that the elasticity is less atthe edges means that during use, in particular in training pants, thelaminate has less propensity to become unstuck at the outer edges of theinterface between the non-woven materials and the elastomer, under theeffect of numerous successive stretching actions realised by the userduring use and each time he closes the nappy.

According to a preferred embodiment of the invention, the curvereproducing the elasticity as measured by elongation at 10 Newton (in %elongation) as a function of the distance in mm from the measuring pointof the left edge of said activated width shows, at each measuring pointin the increasing section, or left region, an essentially non-zerogradient which is less than 50%/mm, preferably less than 25%/mm, morepreferably less than 20%/mm, for example less than 15%/mm, for examplebetween 50 and 5, for example between 25 and 5, particularly between 15and 5.

According to a preferred embodiment, the laminate comprises at least twoelastic films each having a width, the elasticity curve of the activatedwidth on the right being mirror symmetrical to the elasticity curve ofthe activated width on the left, and in particular the gradient inabsolute value of the elasticity curve in the right section of decreaseof the left activated width being less than or equal to that of the leftsection of increase of the left activated width, and in particular isless than 20, particularly less than 12, more particularly less than 10,even more particularly less than 7.

The elasticity curve preferably has a maximum for a measuring pointwhich is essentially in the middle of said width of the laminate.

BRIEF DESCRIPTION OF THE DRAWINGS

A preferred embodiment of the invention is shown in the drawings, givenmerely by way of example, and in which:

FIG. 1 is a perspective view of a device according to the invention;

FIG. 2 is a cross-sectional view of a schematised section of the deviceof FIG. 1;

FIG. 3 is a schematic view of a composite obtained through the methodimplemented in the devices of FIGS. 1 and 2, having two elastic films;

FIG. 4 is a cross-sectional view of a part of the composite of FIG. 3,in the non-stretched state;

FIG. 5 is a cross-sectional view of the part of the composite of FIG. 4,in the stretched state;

FIG. 6 is a cross-sectional view of a composite similar to that of FIG.3;

FIG. 7 is a view equivalent to that of FIG. 6 for the composite of FIG.3;

FIG. 8 shows an example of a graph reproducing the curve for elasticityvariation along the width direction in a width of a laminate accordingto the invention, in the case of a laminate of FIG. 6; and

FIG. 9 shows an example of a graph reproducing the curve for elasticityvariation along the width direction in a width of a laminate accordingto the invention, in the case of a laminate of FIG. 7.

PREFERRED EMBODIMENT FOR CARRYING OUT THE INVENTION

The device of FIG. 1 comprises two extruders 101, 102 which form,through extrusion, two webs 201, 202 of elastomer film which, aftercooling in an intermediate cooling unit 2000, by belt 203 and idler 204systems regulated in temperature, are transported to two rolls whichsimultaneously receive two plies of non-woven material 301 and 401 to besecured there with glue 501 between the non-woven materials in a fixingunit 500, whereby the non-woven materials themselves are stuck to eachother by the glue 501 in the sections where there is no elastic film.The non-woven material 301 is unrolled from a reel 402. The secondnon-woven material 401 is unrolled from a reel 402. The compositeconstituted by the non-woven materials 301 and 401 and the elastic films201, 202, namely the composite 601, is then cut to the correct width ina width cutting system 700 comprising circular knives 701 which passinto a soldering unit 800 allowing soldering of the longitudinal edges.The non-woven materials are finally activated with a view to breakingthem in an activation unit 900. The activation unit 900 comprises afirst roll 901 having teeth 902 and a second roll 903 having teeth 904.The teeth of the toothing 901 engage in the teeth of the toothing 904.

A tension-regulating idler roll 1000 is arranged at the entrance to theactivation unit 900 and works in cooperation with a motor driving one ofthe toothed activation rolls in rotation in such a way as to keep thelongitudinal tension of the laminate constant during its activation.

The relative speed of unrolling of the roll 1000 in relation to thespeed of unrolling of the toothed rolls is such that the composite 601undergoes a longitudinal tension during its movement and in particularwhen it is between the toothing.

This longitudinal tension is regulated to at least 1 Newton (N) for 10mm of width and 100 gm² of said width of laminate to be activated (thatis to say of the laminate solely where there is an interface between anelastomer and at least one ply of non-woven material); preferably, thistension is at least 2 N/10 mm/100 gm², more preferably at least 2.5, forexample between 1.2 and 8, particularly between 2 and 5, for exampleequal to 2.6.

It is also possible to impart a tension of non-woven material of atleast 0.64 Newton (N) for 10 mm of width and 100 gm² of ply of non-wovenmaterial alone; preferably, this tension is at least 0.9 N/10 mm/100 gm²of non-woven material, more preferably at least 1.2, for example between0.65 and 3, particularly between 1 and 2, for example equal to 1.3.

The elastic material may or may not have thermo-shrinkingcharacteristics. It can be formed, in particular, from polymers such ascopolymers of different types of monomer patterns, for examplealternating such as A-B, or in sequence, for example A-A-A-B-B-B, orstatistic, for example A-A-B-A-B-B-A-A-A-B-A, of which the whole of thenetwork obtained can have different structures, either linear of thetype A-B-A, or radial of the type (A-B)n, index n (n>2), or diblock ofthe type A-B, which are elastomers, for example the copolymersstyrene/isoprene (SI), styrene/isoprene/styrene (SIS),styrene/butadiene/styrene (SBS), styrene-ethylene/butylene-styrene(SEBS), styrene-ethylene/propylene-styrene (SEPS) or SIBS. Mixtures ofthese elastomers with each other or with non-elastomers modifyingcertain characteristics other than elasticity may also be considered.For example up to 50% by weight but, preferably, less than 30% by weightof polymer can be added in order to modify certain characteristics ofthe base materials (elasticity, heat resistance, processability, UVresistance, dye, . . . ), such as styrene polyvinyls, polystyrenes orpoly α-methyl-styrene, epoxy polyesters, polyolefines, for examplepolyethylenes, or certain acetates of ethylene/vinyl, preferably thoseof high molecular weight.

The elastic material can be, in particular, a styrene-isoprene-styrene,available for example from Kraton Polymers under the name KRATON D(trade mark filed), or DEXCO POLYMERS LP under the name VECTOR SBC 4211(trade mark filed). A thermo-plastic elastomer of polyurethane can alsobe used, in particular PELLATHANE (trade mark filed) 2102-75A of The DowChemical Company. A styrene-butadiene-styrene can also be used, inparticular KRATON D-2122 (trade mark filed) of Kraton Polymers, orVECTOR SBC 4461 (trade mark filed) of Dexco Polymers LP. Astyrene-ethylene/butylene can also be used, in particular KRATON G-2832(trade mark filed) of Kraton Polymers or a sequencedstyrene-ethylene-butylene-styrene copolymer (SEBS), in particular KRATON(trade mark filed) G2703. A copolymer of isooctyl acrylate and ofacrylic acid can also be used according to the monomer ratios of 90/10.A sequenced polyamide polyether copolymer PEBAX (trade mark filed) 2533of Arkema can also be used.

Other possible materials are polyolefine polymers, principallycopolymers of ethylene and/or propylene, having characteristics ofelastomers, in particular originating from metallocenic catalysis suchas VISTAMAXX VM-1120 (trade mark filed), available from Exxon MobilChemical or also charged polymers EPDM of the Santoprene type.

It is also possible according to the invention to use a glue such as nonreactive hot melt glues, for example H2511 of Bostick, or a reactive PUglue, particularly AX75E of Bostick. These glues will preferably have achemical nature similar to that of the elastomer film described above.For example if one of these glues is analysed with an infraredspectrometer in order to identify the chemical functions, or a liquidchromatograph for separating and quantifying the substances, traces willpreferably be found of one or more components or of their derivatives ofthe substance or substances of the elastomer film.

These glues will preferably have a base of SIS, SBS, SEBS and SEPS,allowing good affinity with film through similar chemical substances.

The layer of glue preferably has a grammage of less than 23 g/m², moreparticularly less than 15 g/m², particularly less than 12 g/m², morepreferably less than 8 g/m².

With regard to the non-woven materials, it is possible to usepolypropylene, polyester and all other materials usual in the field. Itis also possible to play on the elongation for the transverse fractureof the non-woven materials to facilitate the activation to the maximum.

FIG. 7 shows a laminate such as obtained on leaving the device of FIG.1, after passage through the activation toothing. The composite 601comprises an upper ply of non-woven material 301 and a ply of non-wovenmaterial 401, between which two elastic films 201 and 202 of smallerwidth are sandwiched.

FIG. 3 shows, according to a sectional view, transversely to the machinedirection (direction of the X's), that is to say the direction of the Ysin which the laminate of FIG. 7 extends in length. This laminate isconstituted by two plies of non-woven material 301 and 401 having alarge width, for example a width of 170 mm here. Two elastomer films 201and 202 of small width, for example of 45 to 55 mm, are sandwichedbetween the two plies of non-woven material. Two layers of glue 501secure each non-woven material to one of the faces of the elastomerfilms and, when there is no elastomer film, to the other non-wovenmaterial.

For the elastic films, the layers of glue have the form of stripsparallel to each other, at a distance from each other, a distance whichmay be zero and between for example 0 mm and 2 mm, whereas the layer ofglue 501 is continuous between the non-woven materials where there is noelastic film.

After formation of the laminate, the two plies of non-woven material, atthe level of at least one elastomer film, are activated through passagebetween activation rolls, that is to say, these two non-woven materials,in the section covering the at least one elastomer film, are broken in apreferential way in cross direction (or transverse direction) to formsorts of grooves in the transverse direction so that, at the level ofthe two elastomers, the laminate has an elasticity in the transversedirection corresponding essentially to that of the elastomer films.

In order to realise this breaking, the laminate is passed while holdingit in its central section where the grooves are to be formed, throughapplication of an elastic strip which plates the laminate by covering itand the laminate is then stretched and also the elastic strip which isin contact with it, distorting them in order to bring the fibres of thenon-woven material of the laminate apart from each other, breaking thenon-woven material, the elastic film and the elastic strip during thisstretching. Once the distortion is complete the elastic film and theelastic strip return to their non-distorted initial state whereas thenon-woven material is broken permanently.

After the coming apart (de-cohesion of the fibres from each other), thefibres of the non-woven materials tend to regroup at the strips of gluein order to form monticules of non-woven materials, whereas between thestrips of glue the fibres of non-woven materials, by reason of thebreaking, are more rare and are more scattered. There are thus zones (atthe strips of glue) where the non-woven material is of greater thicknessthan in the intermediate zones (where there is no glue), or possibly inthe extreme case, there may no longer be any non-woven material. In thenon-stretched state of the laminate the zones of greatest thickness comeinto lateral contact (by their edge parallel to the transversedirection) with each other and, when the laminate is stretched, thezones of greatest thickness are distanced from each other, whereby theintermediate zones thus appear, either without non-woven material orwith a smaller thickness of non-woven material.

In FIG. 6 which shows the case of a laminate only having only a singleelastic film 203, at least one zone (in particular the entirety) of thecentral region 30 has an elasticity which is greater than the elasticityof the edge regions 31 and 32, measured in an area of these edgeregions, particularly 10% greater, for example 20% greater.

In FIG. 7 at least one zone (particularly the entirety) of the twocentral regions 30 has an elasticity greater than the elasticity of theedge regions 31 and 32, measured in a zone of these edge regions,particularly 10% greater, for example 20% greater.

In FIG. 5, the strips 501 of glue, spaced apart from each other, and thenon-woven material 301 comprise zones 22 of greater thickness (inrelation to the thickness of the non-woven material before breaking) andzones 23 of smaller thickness (in relation to the thickness of thenon-woven material before breaking) which appear more clearly when thelaminate is stretched.

The elastic film has a width 1 perpendicularly to the direction ofplacing on the ply of non-woven material. It has a surface, on the sideof the non-woven material 301, which is planar. In longitudinal sectionthis surface is in the form of a straight line. No fibre of thenon-woven material is immersed in the material of the elastic film andall the fibres are on the same side of this straight line, and this isthe case regardless of the longitudinal section.

In the case of the laminate of FIG. 6, the elasticity of the left region31 of the laminate increases from the left edge 33 of said activatedwidth 1 of laminate towards the middle 34 of this said width. Theelasticity of the right region 32 decreases from the middle 34 towardsthe right edge 35. The elasticity can be measured by the elongation testat 10 Newton and is described below.

As seen in FIG. 8, the elasticity has a lower gradient than 0.21, beingessentially symmetrical in relation to the centre of said width.

In the case of the laminate of FIG. 7, the first activated width 11 oflaminate has a left region 40 of which the elasticity increases from theleft edge 36 towards the middle 37 and a right region 41 of which theelasticity decreases from the middle 37 towards the right edge 38. Asseen in FIG. 9, the gradient (in absolute value) at the left edge isgreater than the gradient at the right edge. The gradient at the leftedge is less than 0.21 while at the right edge it is less than 0.1.

The second activated width 12 of laminate has a left region 42 of whichthe elasticity increases from the left edge 39 towards the middle 44 anda right region 43 of which the elasticity decreases from the middle 44towards the right edge 45. As seen in FIG. 9, the gradient (in absolutevalue) at the right edge is greater than the gradient at the left edge.The gradient at the left edge is less than 0.21 while at the right edgeit is less than 0.1. The elasticity curves in the two activated widthsare mirror symmetrical.

The fact that the elasticity is lower at the edges compared to themiddle means that the laminate is more resistant to the connectionbetween the non-woven material and elastomer becoming unstuck; inparticular it only becomes unstuck at the end of a number of lateralstretching actions (carried out by the user, particularly of trainingpants, when he closes the training pants by stretching the closing tabsrealised on the basis of the laminate of the invention, in order toensure that the nappy is well adapted elastically to the contour of thebaby) much more than is the case of laminates of the prior art, of whichthe elasticity is essentially uniform. It follows that according to theinvention it is possible to omit the provision of solder lines along thelongitudinal edges 33, 35, 36, 38, 39, 45 of the laminates, or toprovide a glue with lower sticking power. However, quite clearly, it ispossible to choose, without going outside of the field of protection ofthe invention, to always provide such solder lines or glues with greatsticking power in order to obtain a laminate which is even moreresistant to becoming unstuck.

In order to measure the elasticity and to realise the elasticity curve(FIGS. 8 and 9) by the elongation test at 10 N, a main sample is takenfollowing activation of for example 45 mm activated width and 45 mm longand 9 measuring samples are formed, each centred on the point at whichthe elasticity is to be measured, each measuring sample being in theform of a strip of for example 5 mm in width and 45 mm in length, whichis stretched with the aid of a dynamometer with jaws (particularly thatindicated below) from its initial non-stretched length, with a force of10 N, at an ambient temperature of 23° C. at +/−2°, a relative humidityof 50%, +/−5% and a normal atmospheric pressure. The elongation obtainedis thus measured as a percentage. Two or three main samples arepreferably taken in order to carry out the measurements several times(at least three times) and the average value is taken for eachelasticity value shown in the graphs of FIG. 8 or 9.

At each measuring point the gradient of the elasticity curve at themeasuring point (necessarily positive, the horizontal not having agradient) is calculated as being the ratio of the difference between theelasticity value measured at the measuring point and the elasticityvalue measured at the preceding measuring point on the width dimension(distance between the two consecutive measuring points) of the measuringsample.

It is thus possible for example to measure the elasticity of a laminatein determining the remanence thereof by the following test:

The sample is conditioned in a normal atmosphere such as defined in theASTDM 5170 norm, temperature of 23° C.+/−2° C. and relative humidity of50%+/−5%.

The dynamometer apparatus used is in accordance with the EN 10002 norm,in particular the Synergie 200, 1 column, available from MTS SystemsCorp., USA, together with utilisation software TESTWORKS 4.04B.

The sample is prepared by cutting the elastic product (for example thelaminate of the invention) with a cutter or scissors into a sample of 45mm of width in the machine direction (MD) (perpendicularly to the planeof FIG. 1) and a length in the cross direction (CD) (horizontaldirection in FIG. 1) of 60 mm.

(Anti-sliding) reinforcements are positioned, for example a ply ofnon-woven material, in order to avoid the sliding and the start offracture of the sample between the jaws by fixing them with a doubleface on each side of the elastic zone to be tested and on each side, asrepresented schematically in FIG. 3;

The parameters are selected as follows:

-   -   Inter-jaw distance: 20 mm    -   Machine speed: 254 mm/mn    -   Number of cycles: 2    -   Elongation of the product: 100% at constant speed.

The product is stretched at 100% by vertical displacement of the upperjaw, the lower jaw being fixed, then it is maintained in the positionfor 30 seconds, and then the initial position is resumed at constantspeed, in which it is left for 60 seconds (end of the first cycle), thenit is again stretched at 100%, it is maintained for 30 seconds and thenthe initial position is resumed (end of second cycle). The curve is thusobtained giving the stretching force as a function of the elongation in%, this exhibiting a hysteresis which allows the set to be determined bythe following calculating formula:SET=L1−L10With:

-   -   L0: intersection point with the axis of the X's (elongation in        %) at the start of the test, namely the start of the first        cycle.    -   L1: intersection point with the axis of the X's (elongation in        %) at the start of the second cycle after the return to the        original position and a wait of 60 seconds.

When the laminate has been obtained, it is then subjected to anactivation, that is to say the elastic capacities of the elastic filmimprisoned between the two non-woven materials which are not elastic arereleased.

In the case of the present invention the appearance of the non-wovenmaterials after the activation has scarcely been modified, in the sameway as the width of the film and its elastic properties. In particularthe non-woven materials are softer to touch and irritate the skin of thewearer of the nappy less.

A non-woven material is a textile surface obtained by mechanical and/orchemical and/or thermal bonding of textile fibres arranged in webs,excluding weaving or knitting (cf Lexique des fils et des étoffes, ISBN:2-9509924-1-1).

Thus, a non-woven material is a cluster of fibres of small dimensionswhich are associated with each other by mechanical compacting, by mixingwith a bonding material or by partial fusion of the non-woven material.When the non-woven material is stretched according to the invention inorder to activate it, the small fibres compacted with each other areseparated in order to bring them apart from each other. Thisbringing-apart involves breaking of the non-woven material. The fibresare not necessarily stretched and, moreover and in general, taking theirsize into account, are not stretched. If they are to be stretched, it ispossible to use a so-called “incremental” activation system. However,this system requires a complex installation, with toothed rolls whichengage in each other, and according to the invention this can beomitted.

In the present invention the terms film or elastic laminate areunderstood to be a film or a laminate which have, according to thepreceding test, a remanence or SET of less than 15%, preferably lessthan 10%, more preferably less than 5% for a stretching of 100% of theinitial width thereof.

An elastic material is understood to be a material such as a film,constituted solely by this material, which is elastic. Elasticity is thephysical property of a body to resume its initial form after suppressionof the load on it.

What is claimed is:
 1. A laminate having a laminate length in alongitudinal direction (MD) and a laminate width in a transversedirection (CD), said laminate comprising at least one ply of non-wovenmaterial and at least one elastic film secured on said at least one plyof non-woven material, said laminate having been activated so as to havean elasticity in at least one activated region having an activatedregion width in the CD direction extending between a left edge and aright edge, wherein along said activated region width in the CDdirection, said elasticity increases along a left section of theactivated region width starting from a left point a distance of 2.5 mmfrom the left edge and decreasing along a right section of the activatedregion width ending at a right point a distance of 2.5 mm from the rightedge.
 2. The laminate of claim 1, wherein a curve reproducing theelasticity of the laminate in said at least one activated region alongan activated region width in the CD direction, as measured by theelongation at 10 Newton (in % elongation), as a function of a distancein millimeters from the left edge of said at least one activated widthpresents along said left section a gradient which is less than 50%/mm.3. The laminate of claim 1, wherein said at least one elastic filmcomprises a left elastic film and a right elastic film, said laminatehaving been activated so as to have an elasticity in both a left filmactivated region having a left film activated region width in the CDdirection and in a right film activated region having a right filmactivated region width in the CD direction, whereby the elasticity curvereproducing the elasticity of the laminate in the right film activatedregion in the CD direction is mirror symmetrical to the elasticity curvereproducing the elasticity of the laminate in the left film activatedregion in the CD direction, both elasticity curves having respectiveleft and right sections and the gradient in absolute value of theelasticity curve in the right section of the left film activated widthbeing less than or equal to that in the left section of the left filmactivated width.
 4. The laminate of claim 3, wherein said elasticitycurve in the right section of the left activated width has a gradientwhich is less than 20%/mm.
 5. The laminate according to one of the claim2, characterised in that the elasticity curve has a maximum for ameasuring point essentially in the middle of said activated width of thelaminate.
 6. The laminate of claim 1 wherein said elastic film issecured to said at least one ply by a bonding material.
 7. The laminateof claim 6 wherein said bonding material is a glue.
 8. The laminate ofclaim 1 wherein there are two plies on non-woven material, said elasticfilm being sandwiched between said two plies of non-woven material. 9.The laminate of claim 8 wherein said elastic film is secured to said twoplies of non-woven material by a bonding material.
 10. The laminate ofclaim 9 wherein said bonding material is a glue.
 11. The laminate ofclaim 1 wherein the elasticity is measured by the elongation test of 10Newton.
 12. The laminate of claim 8 wherein the elasticity is measuredby the elongation test of 10 Newton.
 13. The laminate of claim 2 whereinthe gradient is less than 25%/mm.
 14. The laminate of claim 2 whereinthe gradient is less than 20%/mm.
 15. The laminate of claim 2 whereinthe gradient is less than 15%/mm.
 16. The laminate of claim 2 whereinthe gradient is in the range of 5% to 50%/mm.
 17. The laminate of claim2 wherein the gradient is in the range of 5% to 25%/mm.
 18. The laminateof claim 2 wherein the gradient is in the range of 5% to 15%/mm.
 19. Thelaminate of claim 4, wherein said elasticity curve in the right sectionof the left film activated width has a gradient which is less than12%/mm.
 20. The laminate of claim 4, wherein said elasticity curve inthe right section of the left film activated width has a gradient whichis less than 7%/mm.
 21. A laminate having a laminate length in alongitudinal direction (MD) and a laminate width in a transversedirection (CD), said laminate comprising a least one ply of non-wovenmaterial and at least one elastic film secured on said at least one plyof non-woven material; said laminate having been activated so as to havean elasticity in at least one activated region having an activatedregion width in the CD direction extending between a left edge and aright edge; said elastic film having a constant thickness along saidactivated region width; wherein along said activated region widthstarting in the CD direction said elasticity increases along a leftsection of the activated region width starting from a left point adistance of 2.5 mm from the left edge and decreases along a rightsection of the activated region width ending at a right point a distanceof 2.5 mm from the right edge.